Disk drive device

ABSTRACT

A disk drive device includes a base member; a hub on which a recording disk is placed; a bearing unit arranged on the base member for rotatably supporting the hub; and a spindle drive unit for rotationally driving the hub, wherein the spindle drive unit includes a stator core having salient poles, a coil wound around each of the salient poles, and a magnet having a plurality of magnetic poles arranged in a circumferential direction opposed to the salient poles, the hub includes an outer cylindrical portion formed of a magnetic material and engaged with an inner periphery of the recording disk, and an inner cylindrical portion fixing an outer periphery of the magnet, the number of magnetic poles is an even number in a range of 10 to 16, and the number of salient poles is a multiple of 3 in a range of 12 to 24.

CROSS-REFERENCE TO RELATED APPLICATION

This application is based on Japanese Patent Application No. 2010-092827filed with the Japan Patent Office on Apr. 14, 2010, the entire contentof which is hereby incorporated by reference.

BACKGROUND OF THE INVENTION

1. Technical Field

The invention relates to a disk drive device including a hub on which arecording disk is to be placed.

2. Related Art

In recent years, in a disk drive device such as a HDD, stiffness of abearing is enhanced by providing a fluid dynamic bearing unit. The diskdrive device having the fluid dynamic bearing unit is mounted in a smallportable device in some cases. It is desired that a portable device befurther reduced in thickness and weight. It is also desired that thedisk drive device be further reduced in thickness and weight.

For example, JP-A-2007-198555 discloses a disk drive device having afluid dynamic bearing unit in which a width of a first radial dynamicpressure groove in its axial direction is narrower than that of a secondradial dynamic pressure groove in its axial direction.

SUMMARY

To thin the disk drive device, it is necessary to thin a spindle driveunit and the fluid dynamic bearing unit. If the spindle drive unit isfurther thinned, a torque is reduced in some cases, and rotation of adisk may become unstable. If the fluid dynamic bearing unit is furtherthinned, stiffness of the fluid dynamic bearing unit is reduced in somecases, and rotation of the disk may become unstable. Therefore, theconventional disk drive device is disadvantageous in that if therotation becomes unstable, there is a possibility that a failure occursin a normal read operation and a normal write operation of magnetic datain the worst case.

It is an object of one aspect of the invention to provide a thinner diskdrive device capable of stably rotating a recording disk.

The disk drive device of the one aspect of the invention includes: abase member; a hub on which a recording disk is to be placed; a bearingunit arranged on the base member for rotatably supporting the hub; and aspindle drive unit for rotationally driving the hub. The spindle driveunit includes a stator core having salient poles, a coil wound, aroundeach of the salient poles, and a magnet having a plurality of magneticpoles arranged in a circumferential direction so as to be opposed to thesalient poles. The hub includes an outer cylindrical portion formed of amagnetic material and adapted to be engaged with an inner periphery ofthe recording disk, and an inner cylindrical portion fixing an outerperiphery of the magnet. The number of magnetic poles is an even numberin a range of 10 to 16, and the number of salient poles is a multiple of3 in a range of 12 to 24.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing and other objects, features, aspects and advantages of theinvention will become more apparent from the following detaileddescription when taken in conjunction with the accompanying drawings, inwhich:

FIGS. 1A and 1B illustrate a disk drive device according to anembodiment;

FIG. 2 is a sectional view of a portion of the disk drive deviceaccording to the embodiment;

FIG. 3 is a sectional view of a hub according to the embodiment;

FIG. 4 is a sectional view of a portion of a disk drive device accordingto a comparative technique; and

FIGS. 5A to 5C illustrate a coil forming method according to theembodiment.

DESCRIPTION OF EMBODIMENTS

A preferred embodiment of the invention will be described below withreference to the accompanying drawings, in which like referencecharacters designate similar or identical parts throughout the severalviews thereof.

The disk drive device of the one aspect of the invention includes: abase member; a hub on which a recording disk is to be placed; a bearingunit arranged on the base member for rotatably supporting the hub; and aspindle drive unit for rotationally driving the hub. The spindle driveunit includes a stator core having salient poles, a coil wound aroundeach of the salient poles, and a magnet having a plurality of magneticpoles arranged in a circumferential direction so as to be opposed to thesalient poles. The hub includes an outer cylindrical portion formed of amagnetic material and adapted to be engaged with an inner periphery ofthe recording disk, and an inner cylindrical portion fixing an outerperiphery of the magnet. The number of magnetic poles is an even numberin a range of 10 to 16, and the number of salient poles is a multiple of9 in a range of 12 to 24.

According to this aspect, the number of salient poles is as many as 12or more. For this reason, the total number of turns of the coil can beincreased. According to this configuration, a sufficient total number ofturns of the coil can be secured even in a thinner disk drive device. Itis therefore possible to improve reduction in a torque, and thus tostabilize rotation of the recording disk.

According to this aspect, it is possible to further thin the disk drivedevice and stabilize the rotation of the recording disk.

In the following description, the same symbols are allotted to identicalor equivalent constituent elements and members illustrated in thedrawings, and redundant description is not repeated as appropriate.Dimensions of members in each of the drawings are scaled up or down asappropriate to facilitate understanding of the invention. In thefollowing description, a lower side in the drawings is expressed as“lower, down or downward” and an upper side in the drawings is expressedas “upper, up or upward” for the sake of convenience.

A disk drive device 100 as one example that is assumed in thisembodiment is adapted to be provided with and rotationally drive aso-called 2.5-inch hard disk (recording disk 1) made of glass and havingan outer diameter of about 65 mm, an inner diameter of about 20 mm and athickness of about 0.75 mM.

FIGS. 1A and 1B illustrate the disk drive device 200 according to theembodiment. FIG. 1A is a plan view of the disk drive device 100, andFIG. 1B is a side view of the disk drive device 100. FIG. 1A illustratesa state where a top cover 2 is removed. FIG. 2 is a sectional view of aportion of the disk drive device 100 according to the embodiment. FIG. 3is a sectional view of a hub 4 according to the embodiment. FIGS. 2 and3 are sectional views taken along the line A-B in FIG. 1A.

The disk drive device 100 rotationally drives the recording disk 1 thatis a magnetic recording medium.

The disk drive device 100 includes a stator 7 having a fixed member thatdoes not rotate, and a rotor 8 having a rotating member.

First, the stator 7 will be described. The stator 7 includes a chassis10, a head drive unit 17, the top cover 2, a screw 9, a stator core 11,a coil 12, a housing 13 and a sleeve 14.

The chassis 10 has a substantially rectangular cross section with anopen top. As illustrated in FIGS. 1A and 1B, the chassis 10 includes abase member 3 and a peripheral annular wall portion 15.

The base member 3 is a flat, depressed portion. As illustrated in FIG.2, the base member 3 includes a bearing hole 3A into which the housing13, the sleeve 14 and a shaft 16 are inserted.

As illustrated in FIGS. 1A and 1B, the peripheral annular wall portion15 is formed into a wall-like shape so as to surround the base member 3.An outer circumferential surface of the peripheral annular wall portion15 is rectangular in shape. An inner circumferential surface of theperipheral annular wall portion 15 is constituted by an annular portion15A surrounding the recording disk 1 and a rectangular portion 15Bsurrounding a region where the head drive unit 17 is placed.

The peripheral annular wall portion 15 serves as a support member forthe disk drive device 100 that supports the disk drive device 100 in arotational axis direction of the shaft 16. The base member 3 serves as asupport member for the disk drive device 100 that supports the diskdrive device 100 in a direction perpendicular to the rotational axisdirection of the shaft 16.

The top cover 2 covers a space formed by the depressed portion (basemember 3) of the chassis 10. As illustrated in FIG. 1B, the top cover 2is provided on an upper end of the peripheral annular wall portion 15.The top cover 2 is fixed to the peripheral annular wall portion 15 byengaging a screw 9 with a screw hole 15C formed in an upper end surfaceof the peripheral annular wall portion 15. The space formed by thedepressed portion (base member 3) of the chassis 10 is hermeticallyclosed with the chassis 10 and the top cover 2. A clean air space isformed in the space. The clean air space is filled with clean air fromwhich particles are removed. The recording disk 1, the rotor 8 and thehead drive unit 17 are arranged in the clean air space.

The stator core 11 shown in FIG. 2 is fixed to the base member 3. Thestator core 11 includes an annular portion and a plurality of salientpoles extending from the annular portion in a radial direction. Thestator core 11 is formed by laminating a plurality of magnetic platematerials such as silicon steel plates and applying insulating, coatingsuch as electrodeposition coating or powder coating to a surface of thelaminated magnetic plate materials. The stator core 11 may havedimensions of 9 mm in inner diameter of the annular portion, and 18 mmin diameter of a circumcircle of the salient poles, for example. Thestator core 11 may have a thickness of 1 mm by laminating five siliconsteel plates of 0.2 mm in thickness.

The coil 12 is a three-phase coil wound around the salient poles of thestator core 11. The coil 12 is made of a wire 25. The wire 25 is woundaround one of the salient poles of the stator core 11 a predeterminednumber of turns from its lower side and is then continuously woundaround an adjacent salient pole of the stator core 11 from its upperside. An axial dimension of the coil 12 wound around the salient polesmay be 0.6 mm, for example. The Wire 25 is continuously wound around thesalient poles of the stator core 11 a predetermined number of turns.Then, a winding end of the wire 25 is drawn out from the lower side of asalient pole of the stator core 11. The winding end of the wire 25 isfurther drawn out to a side opposite to the base member 3 through a wirehole 3E formed in the base member 3. Then, the wire 25 is electricallyconnected to a wiring member 26 arranged on a back surface of the basemember 3. The drawn-out winding end of the wire 25 is fixed by means ofan adhesive so that the winding end is not untied. By fixing the windingend in this manner, the wire 23 is prevented from being broken by such aphenomenon that the wire 23 resonates with ultrasound and oscillateswith large amplitude during ultrasonic cleaning.

The housing 13 is formed into a bottomed cup shape. A portion of anouter circumferential surface of the housing 13 is fixed to the bearinghole 3A formed in a substantially central portion of the base member 3.A bottom portion is formed on a lower end of the housing 13. The bottomportion is sealed so that a lubricant does not leak outside.

The sleeve 14 has a substantially cylindrical shape, and is insertedinto the housing 13. A portion of an outer circumferential surface ofthe sleeve 14 is fixed to an inner circumferential surface of thehousing 13 by adhesion or the like. An overhanging member 19 overhangingradially outward is fixed to an open end surface 14A on an upper side ofthe sleeve 14.

The overhanging member 19 cooperates with a later-described suspendingportion 20 mounted on the hub 4 to limit movement of the hub 4 in itsaxial direction. According to this configuration, the overhanging member19 and the suspending portion 20 cooperate with each other to preventthe rotor 8 from being separated.

Next, the rotor 8 will be described. The rotor 8 includes the shaft 16,the hub 4 and the magnet 21.

The shaft 16 serves as a rotary shaft of the disk drive device 100. Theshaft 16 is inserted into the sleeve 14. An upper end of the shaft 1′ isfixed to a shaft hole 4M formed in a central portion of the hub 4.

The hub 4, on which the doughnut-shaped recording disk 1 is placed, hasa substantially saucer-shape.

The magnet 21 is fixed to an inner cylindrical portion 4D of the hub 4,and has a substantially cylindrical shape. The magnet 21 is mounted onthe hub 4 so that the magnet'21 is opposed to tips of the salient polesof the stator core 11. The magnet 21 is made of a Nd—Fe—B(neodymium-iron-boron) based rare-earth material. A surface of themagnet 21 is subjected to anticorrosive processing by electrodepositioncoating or spray coating. The magnet 21 includes a plurality of drivingmagnetic poles along a circumferential direction of an inner peripheralportion thereof. The magnet 21 may have a substantially ring shape of18.4 mm inner diameter, 20.4 mm outer diameter and 2 mm thickness in itsaxial direction, for example.

A structure of the hub 4 will be described concretely with reference toFIG. 3. The hub 4 is made of a soft magnetic material (e.g., SUS430F).It is preferable that the entire hub 4 be made of a magnetic material interms of producing a magnetic shielding effect. The hub 4 is formed intothe predetermined substantially saucer-shape by pressing or cutting aniron steel plate. Stainless steel under the trade name DHS1 produced byDaido Steel Co., Ltd. is preferable in that an amount of outgas is smalland it is easy to machine this stainless steel. Further, stainless steelunder the trade name DHS2 produced by Daido Steel Co., Ltd. is morepreferable in that it has a more excellent corrosion resistance.

As illustrated in FIG. 3, the shaft hole 4M is formed in a centralportion of the hub 4. An annular central portion 4I is formed around theshaft hole 4M. An axial dimension of the shaft hole 4M is larger thanthat of a portion of the central portion 4I opposed to an upper endsurface of the sleeve 14. A portion of an outer circumferential surfaceof the shaft hole 4M projects downward. According to this configuration,bonding surfaces of the hub 4 and the shaft 16 are secured even if thedisk drive device 100 is thinned.

An upper end surface 4A of the hub 4 is divided into upper and lower twostepped portions. The upper stepped portion is the central portion 4I. Alowered portion 4J that is lowered by one step relative to the centralportion 4I is formed annularly around the central portion 4I. An innerdiameter of the lowered portion 4J may be 8 mm, for example. Such aninner diameter is preferable in terms of easy machining. As illustratedin FIGS. 2 and 3, a clamper 29 is arranged on an upper surface of thelowered portion 4J. A cylindrical portion that connects the centralportion 4I and the lowered portion 4J with each other is fitted into acentral hole of the clamper 29. An axial dimension of the cylindricalportion may be 0.8 mm to 0.7 mm, for example. This dimension ispreferable in that projection of the clamper 29 can be suppressed. Aclamper locking portion that locks the clamper 29 is formed on the uppersurface of the lowered portion 4J. More specifically, a plurality ofscrew holes 4K are formed in the upper surface of the lowered portion 4Jin its circumferential direction at equal intervals. These screw holes4K constitute the clamper locking portion. The clamper 29 is locked tothe hub 4 by engaging screws 30 with the screw holes 4K.

As illustrated in FIG. 3, an annular outer cylindrical portion 4B isformed by a cylindrical surface extending downward from an outerperipheral end of the lowered portion 4J. An annular extending portion4C extending radially outward is formed on a lower end of an outercircumference of the outer cylindrical portion 4B. As illustrated inFIGS. 2 and 3, an inner circumferential surface of the central hole ofthe recording disk 1 is engaged with the outer cylindrical portion 4B ofthe hub 4. An end of the recording disk 1 is placed on an upper surfaceof the annular extending portion 40. A diameter of the outer cylindricalportion 4B may be 20 mm. A height difference between the upper surfaceof the annular extending portion 40 and the lowered portion 4J in theaxial direction may be 0.7 mm to 0.8 mm. An outer diameter of theannular extending portion 4C may be 24 mm. By employing such dimensions,the so-called 2.5-inch recording disk 1 can be engaged with highaccuracy.

The annular extending portion 40 hangs clown toward the base member 3,and is located in a radially outward region of an outer periphery of themagnet 21. The annular extending portion 40 serves as a back yoke of themagnet 21. An axial dimension of the annular extending portion 40 may be2.5 mm to 3 mm, for example. This dimension is preferable in thatleakage flux can be suppressed. As illustrated in FIG. 2, the outerperiphery of the magnet 21 is fixed to the inner cylindrical portion 4Dforming an inner surface of the annular extending portion 40.

As illustrated in FIG. 3, an annular projection 45 is formed on a lowersurface of the hub 4. The annular projection 4E projects toward the basemember 3 between the housing 13 and the stator core 11. The annularsuspending portion 20 is fixed to an inner circumferential surface ofthe annular projection 4E of the hub 4 by adhesion (see FIG. 2).

A lower end surface 4F of the hub 4 opposed to the open end surface 14Aof the sleeve 14 is located on a back surface of the central portion 4I.A portion 45 of the hub 4 opposed to the coil 12 is located on a backsurface of the lowered portion 4J.

Some of the members of the disk drive device 100 constitute a bearingunit 5 or a spindle drive unit 6 of the disk drive device 100.

The bearing unit 5 will be described. The bearing unit 5 is arranged onthe base member 3, and relatively rotatably supports the hub 4 (rotor8). The bearing unit 5 includes the shaft 16, the sleeve 14, the housing13, the overhanging member 19 and the suspending portion 20 as describedabove. The bearing unit 5 further includes radial dynamic pressuregrooves 22, thrust dynamic pressure grooves 23 and a capillary sealportion 24 shown in FIG. 2.

The radial dynamic pressure grooves 22 and the thrust dynamic pressuregrooves 23 serve as bearings that rotatably support the hub 4. The twoherringbone-shaped radial dynamic pressure grooves 22 are formed in atleast one of an inner circumferential surface of the sleeve 14 and anouter circumferential surface of the shaft 16 so that the two radialdynamic pressure grooves 22 are vertically apart from each other. Thethrust dynamic pressure grooves 23 have herringbone shapes or spiralshapes. The thrust dynamic pressure grooves 23 are formed in a surfaceof the suspending portion 20 opposed to an open end surface of thehousing 13 and in an upper surface of the suspending portion 20 opposedto a lower surface of the overhanging member 19. The thrust dynamicpressure groove 23 may be formed in at least one of the open end surface14A of the sleeve 14 and the lower end surface 4F of the hub 4 opposedto the open end surface 14A.

Rotation of the shaft 16 makes the radial dynamic pressure grooves 22generate radial dynamic pressure in the lubricant. As a result, therotor 8 is supported in the radial direction. On the other hand,rotation of the suspending portion 20 makes the thrust dynamic pressuregrooves 23 generate thrust dynamic pressure in the lubricant. As aresult, the rotor 6 is supported in a thrust direction.

The capillary seal portion 24 is formed by an inner circumferentialsurface of the cylindrical portion of the suspending portion 20 and theouter circumferential surface of the housing 13. A gap between the innercircumferential surface of the suspending portion 20 and the outercircumferential surface of the housing 13 gradually widens toward itslower open end. A lubricant such as oil is introduced into a spacedefined by the radial dynamic pressure grooves 22, the surfaces opposedthereto, the thrust dynamic pressure grooves 23, the surfaces opposedthereto and the capillary seal portion 24. An interface (liquid surface)where the lubricant and outside air are in contact with each other isset at an intermediate position of the capillary seal portion 24. Thecapillary seal portion 24 can prevent the lubricant from leaking out bycapillary action.

Next, the spindle drive unit 6 will be described. The spindle drive unit6 includes the stator core 11, the coil 12 and the magnet 21 asdescribed above.

The spindle drive unit 6 rotationally drives the rotor 8 including thehub 4. That is, if three-phase substantially sine wave current flowsthrough the coil 12 via the wiring member 26 arranged on the backsurface of the base member 3 by a predetermined drive circuit, the coil12 produces a rotating magnetic field at the salient poles of the statorcore 11. A rotational driving force is generated in the rotor 8including the magnet 21 by interaction between the rotating magneticfield and the driving magnetic poles of the magnet 21, and the rotor 8rotates.

The spindle drive unit 6 will be described in more detail.

A thickness of the disk drive device 100 in its axial direction isdefined as a dimension from the upper end surface of the top cover 2 tothe lower end surface of the base member 3 along a direction of arotation axis of the recording disk 1. To reduce the thickness of thedisk drive device 100, in its axial direction, an axial dimension froman upper end of the hub 4 to a lower end of the base member 3(hereinafter referred to as an axial dimension X) should be reduced. Ifthe axial dimension X is set to 6 mm or less, the axial thickness of thedisk drive device 100 can be set to 7 mm or less even if a dimension ofthe top cover 2 and a gap between the top cover 2 and the hub 4 areadded. If the axial dimension X is set to 5.5 mm or less, the axialthickness of the disk drive device 100 can more easily be set to 7 mm orless.

To reduce the axial dimension X, an axial dimension of a portion of thedisk drive device 100 where the hub 4, the base member 3, the statorcore 11 and the coil 12 are laid on one another in the axial direction(hereinafter referred to as an axial dimension Y) is typically reduced.If the axial dimension Y is set to 5.3 mm or less, for example, theaxial dimension X can be set to 6 mm or less even if a space where theclamper 29 that fixes the recording disk 1 to the hub 4 is arranged istaken into account. If the axial dimension Y is set to 4.8 mm or less,the axial dimension X can easily be set to 5.5 mm or less.

If the hub 4 and the base member 3 are thinned to reduce the axialdimension Y, however, the stiffness of the disk drive device 100 may bereduced. If the stiffness of the disk drive device 100 is reduced, therecording disk 1 oscillates even when the recording disk 1 receives aslight impact. Therefore, recording and reproducing operations of databecome unstable. Hence, an axial dimension between a surface of the coil12 opposed to the hub 4 and a surface of the coil 12 which is opposed tothe base member (hereinafter referred to as an axial dimension Z) may beset to 3 mm or less. It is preferable to set the axial dimension Z to 3mm or less in that it is possible to suppress the reduction in stiffnessof the hub 4 and the base member 3 even if the axial dimension Y is setto 5.3 mm or less. If the axial dimension Z is reduced, the salientpoles of the stator core 11 are also thinned. Therefore, the strength ofthe stator core 11 is reduced, and the stator core 11 may be deformed insome cases in winding of the coil 12. The present inventors confirmed byexperiments that if the axial dimension 7, was 2 mm or more when adiameter of a circumcircle of the salient poles of the stator core 11was in a range of 15 mm to 25 mm, deformation of the salient pole inwinding of the coil 12 fell within a permissible range.

To reduce the axial dimension Z, the coil 12 is typically thinned. Ifthe coil 12 is thinned, the number of turns of the coil 12 that can bewound around the salient poles of the stator core 11 is reduced. If thenumber of turns of the coil 12 is small, a torque of the spindle driveunit 6 is lowered. Therefore, rotation of the recording disk 1 becomesunstable. If the rotation becomes unstable, there is a possibility thata failure occurs in a normal read operation and a normal write operationof magnetic data in the worst case.

To address this concern, according to the disk drive device 100 of, theembodiment, the number of the salient poles of the stator core 11 is 12or more. The number of turns of the coil is increased with the number ofthe salient poles of the stator core 11. Since the number of the salientpoles of the stator core 11 is increased to 12 or more, it is possibleto suppress the reduction in the torque of the spindle drive unit 6caused by the number of turns of the coil 12 even if the coil 12 isthinned. Hence, the recording disk 1 can be rotated in an excellentmanner. To drive the spindle drive unit 6 in three-phase, the number ofthe salient poles of the stator core 11 may be set to a multiple ofthree. Such a configuration is preferable in that a smooth drive torquecan be obtained. If the number of the salient poles of the stator core11 is too large, the salient poles become thinner, and thus, the salientpoles are easily deformed. Therefore, since it becomes necessary tocarefully carry out a machining operation of the stator core 11, laboris required to assemble the disk drive device 100. It is preferable toset the number of the salient poles of the stator core 11 to 24 or lessbecause it is possible to easily carry out the machining operation ofthe stator core 11 even when a diameter of a circumcircle of the salientpoles of the stator core 11 is 25 mm or less.

The inventors found by experiments that if the number of the drivingmagnetic poles of the magnet 21 was small, oscillation caused bypulsation of a torque of the spindle drive unit 6 became, large. If theoscillation of the spindle drive unit 6 is large, a magnetic head of thehead drive unit 17 oscillates, and there is a possibility that a failureoccurs in a normal read operation and a normal write operation ofmagnetic data. To address this concern, in the disk drive device 100 ofthe embodiment, the number of the driving magnetic poles of the magnet21 is set to 10 or more. Since the number of the driving magnetic polesof the magnet 21 is increased to 10 or more, it is possible to suppressthe oscillation of the spindle drive unit 6. If the number of thedriving magnetic poles of the magnet 21 is too large, intervals betweenadjacent magnetic poles become smaller. Therefore, it becomes difficultto sufficiently strongly magnetize the magnetic poles. If themagnetizing strength of the driving magnetic poles of the magnet 21 isinsufficient, a torque of the spindle drive unit 6 is lowered.Therefore, rotation of the recording disk 1 becomes unstable. If therotation of the recording disk 1 becomes unstable, there is apossibility that a failure occurs in a normal read operation and anormal write operation of magnetic data in the worst case. It ispreferable to set the number of the driving magnetic poles of the magnet21 to 16 or less in that it is possible to sufficiently stronglymagnetize the magnetic pole even when the inner diameter of the magnet21 is 25 mm or less.

The inventors confirmed by experiments that if a diameter of acircumcircle of the salient poles of the stator core 11 was in a rangeof 15 mm to 25 mm, an inner diameter of the magnet 21 was in a range of15 mm to 25 mm and an axial dimension Y thereof was in a range of 4.3 mmto 5.3 mm, for example, the number of the driving magnetic poles of themagnet 21 could be set to 10 and the number of salient poles of thestator core 11 could be set to 15. The inventors also confirmed byexperiments that if the above configuration was employed, it waspossible to suppress the reduction in torque of the spindle drive unit6, and thus, excellent rotation of the recording disk 1 was secured andoscillation thereof was reduced. The inventors also confirmed byexperiments that machining of the stator core 11 was facilitated.

The inventors also confirmed by experiments that if a diameter of acircumcircie of the salient poles of the stator core 11 was in a rangeof 15 mm to 25 mm, an inner diameter of the magnet 21 was in a range of15 mm to 25 mm and an axial dimension Y thereof was in a range of 4.3 mmto 5.3 mm, for example, the number of the driving magnetic poles of themagnet 21 could be set to 12 and the number of salient poles of thestator core 11 could be set to 18. The inventors also confirmed byexperiments that if the above configuration was employed, it waspossible to further suppress the reduction in torque of the spindledrive unit 6, and thus, excellent rotation of the recording disk 1 wassecured and oscillation thereof was reduced. The inventors alsoconfirmed by experiments that machining of the stator core 11 wasfacilitated.

The inventors also confirmed by experiments that if a diameter of acircumcircle of the salient poles of the stator core 11 was in a rangeof 15 mm to 25 mm, an inner diameter of the magnet 21 was in a range of15 mm to 25 mm and an axial dimension Y thereof was in a range of 4.3 mmto 5.3 mm, for example, the number of the driving magnetic poles of themagnet 21 could be set to 14 and the number of salient poles of thestator core 11 could be set to 21. The inventors also confirmed byexperiments that if the above configuration, was employed, it waspossible to suppress the reduction in torque of the spindle drive unit6, and thus, excellent rotation of the recording disk 1 was secured andoscillation thereof was reduced. The inventors also confirmed by theexperiment that machining of the stator core 11 was facilitated.

The inventors also confirmed by experiments that if a diameter of acircumcircie of the salient poles of the stator core 11 was in a rangeof 15 mm to 25 mm, an inner diameter of the magnet 21 was in a range of15 mm to 25 mm and an axial dimension Y thereof was in a range of 4.3 mmto 5.3 mm, for example, the number of the driving magnetic poles of themagnet 21 could be set to 16 and the number of salient poles of thestator core 11 could be set to 24. The inventors also confirmed byexperiments that if the above configuration was employed, it waspossible to suppress the reduction in torque of the spindle drive unit6, and thus, excellent rotation of the recording disk 1 was secured andoscillation thereof was reduced. The inventors also confirmed byexperiments that machining of the stator core 11 was facilitated.

The inventors also confirmed by experiments that if a diameter of acircumcircle of the salient poles of the stator core 11 was in a rangeof 15 mm to 25 mm, an inner diameter of the magnet 21 was in a range of15 mm to 25 mm and an axial dimension Y thereof was in a range of 4.3 mmto 5.3 mm, for example, the number of the driving magnetic poles of themagnet 21 could be set to 16 and the number of salient poles of thestator core 11 could be set to 12. The inventors also confirmed byexperiments that if the above configuration was employed, it waspossible to suppress the reduction in torque of the spindle drive unit6, and thus, excellent rotation of the recording disk 1 was secured andoscillation thereof was reduced. The inventors also confirmed byexperiments that machining of the stator core 11 was facilitated.

A concern recognized by the present inventors will be described based ona comparative technique shown in FIG. 4. FIG. 4 is a sectional view of aportion of a disk drive device 200 according to the comparativetechnique. According to the disk drive device 200 of the comparativetechnique, if the disk drive device 200 is thinned, a spindle drive unit52 including a stator core 50 is thinned correspondingly. If the spindledrive unit 52 is thinned, a torque is reduced, and thus, rotation of therecording disk 1 becomes unstable. There is a concern here that if therotation of the recording disk 1 becomes unstable, there is apossibility that a failure occurs in a normal read operation and anormal write operation of magnetic data in the worst case. There is alsoa method using a magnet 54 having a larger diameter to recover thereduced torque. However, according to such a configuration that therecording disk 1 is located in a region which is an extension of anouter periphery of the magnet 54, a back yoke portion 58 of a hub 56located between an inner periphery of the recording disk 1 and an outerperiphery of the magnet 54 is thinned with a diameter of the magnet 54.The back yoke portion 58 is a portion of a magnetic circuit throughwhich a magnetic flux coming from the outer periphery of the magnet 54passes, and if the back yoke portion 58 is thinned, the back yokeportion 58 is magnetically saturated. If the back yoke portion 58 ismagnetically saturated, the magnetic flux is not increased even if themagnetic flux is intensified. Therefore, since an increase in themagnetic flux that contributes to a torque becomes small, the torquecannot be increased. On the other hand, a magnetic flux leaking towardthe recording disk 1 is largely increased. Therefore, according to theconfiguration that the recording disk 1 is an extension of the outerperiphery of the magnet 54, if the back yoke portion 58 is thinned,there is a possibility that a failure occurs in a normal read operationand a normal write operation of magnetic data as a result of the leakageflux. This fact is an inhibition factor in thinning the disk drivedevice 200. If the back yoke portion is thickened in the comparativetechnique, the magnet 54 has to be reduced in dimension correspondingly.Therefore, an increase in torque cannot be expected.

Referring back to FIG. 2, to address this concern according to the diskdrive device 100 of the embodiment, the recording disk 1 is separatedfrom the region on the extension of the outer periphery of the magnet 21in the radial direction. That is, the recording disk 1 is arranged at aposition above the magnet 21 in the axial direction. According to thisconfiguration, it is possible to reduce a magnetic flux leaking towardthe recording disk 1. In addition, as illustrated in FIG. 3, a diameterof the inner cylindrical portion 4D of the hub 4 is larger than that ofthe outer cylindrical portion 4B of the hub 4. As a result, the outerperiphery of the magnet 21 can be increased. Therefore, since an amountof the magnetic flux of the driving magnetic poles of the magnet 21 isincreased, a torque is increased. Thus, it is possible to thin the diskdrive device 100 in a favorable manner. Since the recording disk 1 isarranged at the position above the magnet 21 in the axial direction andseparated from the region on the extension of the outer periphery of themagnet 21 in the radial direction, the back yoke (annular extendingportion 40) of the hub 4 can have a sufficiently large thickness in theradial direction. As a result, even if the magnet 21 having largerenergy product is employed, influence of the leakage flux can be reducedand a torque can be increased.

For example, the hub 4 is made of a magnetic material, and an axialdistance between an upper surface of the magnet 21 and an upper surfaceof the annular extending portion 40 on which the recording disk 1 isplaced is set to 1 mm or less. This configuration is preferable in thatthe disk drive device 100 can be made thin. Further, it is preferable toset an axial distance between the upper surface of the annular extendingportion 40 and the upper surface of the magnet 21 to 0.5 mm or more inthat a magnetic flux leaking toward the recording disk 1 can besuppressed. Further, it is advantageous to set an axial distance betweenthe upper surface of the annular extending portion 40 and the uppersurface of the magnet 21 to 0.76 mm, for example, in that the disk drivedevice 100 can be made thin and the leakage flux can be suppressed.

A diameter of a circle connecting tips of the stator core 11 with eachother may be 80% or more of a diameter of the outer cylindrical portion4B of the hub 4. A diameter of a circle circumscribing the salient polesof the stator core 11 may be set to 22 mm, and a diameter of the outercylindrical portion 4B may be set to 20 mm. Since the number of turns ofthe coil 12 can be increased by making the stator core 11 large, atorque can be increased. If the number of turns of the coil 12 is notincreased, the 12 can be thinned. This fact is advantageous in that thedisk drive device 100 can further be thinned. If the diameter of thecircle connecting the tips of the stator core 11 with each other exceeds140% of the diameter of the Outer cylindrical portion 4B, there is apossibility that the leaked magnetic flux of the magnet 21 acts on therecording disk 1. Thus, there is a possibility that a failure occurs ina normal read operation and a normal write operation of magnetic data.Therefore, it is preferable that the diameter of the circle connectingthe tips of the stator core 11 with each other be in a range of 80% to140% of the diameter of the outer cylindrical portion 4B.

The base member 3 has a wire hole 3B through which the wire 25 formingthe coil 12 is inserted. A portion (drawn-out line) of the wire 25forming the coil 12 that is drawn out from the coil 12 is guided to theback surface 3C of the base member 3 through the wire hole 3B. This backsurface 3C is a surface of the base member 3 opposite from a sideopposed to the hub 4 (surface of the base member 3 that is not opposedto the hub 4).

According to the comparative technique shown in FIG. 4, the drawn-outline of the wire 25 is connected to a wiring member 66 by soldering at aposition immediately after the drawn-out line is drawn out from a coil62 (position directly below the coil 62), and a connected portion 68 isformed at this position. A thickness of the wiring member 66 and aheight of the connected portion 68 at the position directly below thecoil 62 become an obstacle to thinning the spindle drive unit 52.

Referring back to FIG. 2, to address this concern in the disk drivedevice 100, the drawn-out line of the wire 25 is drawn out to the backsurface 30 of the base member 3 through the wire hole 313, and iselectrically connected to the wiring member 26 at a position outside ofthe outer diameter of the magnet 21 in the radial direction. Accordingto this configuration, a connection 26A between the drawn-out line andthe wiring member 26 is arranged at a position deviated from below themagnet 21 (spindle drive unit 6). Thus, the spindle drive unit 6 can bethinned by the height of the connection 26A. The number of membersarranged in a region of the base member 3 outside of the magnet 21 inthe radial direction is smaller than the number of members arranged in aregion where the spindle drive unit 6 is arranged. Therefore, the regionof the base member 3 outside of the magnet 21 in the radial directioncan be made thin. The connection 26A can be provided in the thinnedregion of the base member 3.

The base member 3 may be made of metal such as aluminum. In such a case,if the wire 25 drawn out to the back surface 3C of the base member 3directly comes into contact with the base member 3, an electric shortcircuit may be established. To address this concern, a groove 3D isprovided in the back surface 30 of the base member 3. The wire 25 isguided from the wire hole 3D to the wiring member 26 (connection 26A)through the groove 3D. The groove 3D is insulated. As a result, apossibility that an electric short circuit is established between thewire 25 and the base member 3 is decreased. If the groove 3D is combinedwith the configuration that the connection 26A is positioned outside ofthe magnet 21 in the radial direction, the spindle drive unit 6 can bethinned by the thickness of the wiring member 66 and the height of theconnected portion 68 in the comparative technique shown in FIG. 4.Cationic electrodeposition coating (hereinafter referred to as “EDcoating”), for example, may be used for insulating the base member 3produced by aluminum die casting. This insulating process is preferablein that the number of pinholes is reduced.

Next, if the disk drive device 100 is further thinned, the lower surfaceof the hub 4 and the coil 12 wound around the salient poles of thestator core 11 come very close to each other. In this case, apossibility that the coil 12 comes into contact with the rotating hub 4becomes high. Therefore, there is a concern that the coil 12 comes intocontact with the hub 4 and an electric short circuit is established. Toaddress this concern according to the disk drive device 100, a surfaceof the coil 12 opposed to the hub 4 and a surface of the coil 12 opposedto the base member 3 are smoothened such that these surfaces areflattened.

FIGS. 5A, 5B and 5C show a method forming the coil 12 according to theembodiment. FIG. 5A illustrates the coil 12 before it is formed, FIG. 5Billustrates the coil 12 during pressing thereof, and FIG. 5C illustratesthe coil 12 after pressing thereof. As shown in these drawings, the coil12 is formed by sandwiching and pressing the wire 25 wound around thesalient poles of the stator core 11 between a first pressing mold 40 anda second pressing mold 42. The pressing surfaces of the first pressingmold 40 and the second pressing mold 42 are flat. By pressing andflattening the coil 12, an axial dimension of the coil 12 is stabilized.Thus, the possibility that the coil 12 comes into contact with therotating hub 4 can be decreased. Therefore, the axial dimension of thecoil 12 can be reduced.

To address the concern that the coil 12 comes into contact with therotating hub 4, flattening of the wire 25 forming the smoothened coil 12may be set to 90% or less. The flattening of the wire 25 is a ratio ofan axial dimension “b” to a radial dimension “a” of a cross section ofone wire 25 that is expressed in percentage (in practice, the flatteningof the wire 25 differs depending upon portions thereof, but normally,the lowest flattening is used). The following is an expression of theflattening.

Flattening of wire 25=(b/a)×100

When the coil 12 is pressed and formed to limit the dimension of thecoil 12 in its axial direction, a portion of the wire 25 having thelowest flattening is the thickest portion in the axial direction. As aresult, the possibility that the coil 12 comes into contact with therotating hub 4 can further be decreased.

To address the concern that the coil 12 comes into contact with therotating hub 4, a surface of the hub 4 opposed to the coil 12 may beinsulated. As a result, a possibility that an electric short circuit isestablished and a failure occurs in function is decreased. Theinsulating process may be carried out by a film-pasting process forpasting a resin film on a surface of the hub 4 opposed to the coil 12 byan adhesion member. An annular PET (polyethyleneterephthalate) film 27may be pasted on the surface of the hub 4 opposed to the coil 12 by adouble-stick tape. This process is preferable in terms of easy work.

There is a concern that the coil 12 comes into contact with the basemember 3 and an electric short circuit is established. To address thisconcern, a surface of the base member 3 opposed to the coil 12 may beinsulated. As a result, a possibility that the coil 12 comes intocontact with the base member 3 and the electric short circuit isestablished is decreased. The insulating process is realized by EDcoating the base member 3 produced by aluminum die casting. Thisinsulating process is preferable in that the number of pinholes isreduced. An annular PET film 28 may be pasted on the surface of the basemember 3 opposed to the coil 12 by a double-stick tape. This process ispreferable in terms of easy work.

Next, when the disk drive device 100 is thinned, if an axial thicknessof the portion 4H of the hub 4 opposed to the coil 12 is reduced, thestiffness of the hub 4 is lowered and a resonance frequency of the diskdrive device 100 is lowered. As a result of research carried out by theinventors, they found that main factors that determine the resonancefrequency of the disk drive device 100 are the stiffness of the bearingand the stiffness of the hub 4.

If the resonance frequency is lowered, the disk drive device 100 mayresonate with variation in drive torque and large oscillation may occur.There is a concern that this oscillation can cause a failure in a normalread operation and a normal write operation of magnetic data in theworst case. To address this concern, an axial width of the hub 4 opposedto the coil 12 may be larger than an axial width of the base member 3,opposed to the coil 12. This is a relative relation between axialdimensions of the base member 3 and the hub 4 in a region where thespindle drive unit 6 is arranged when the disk drive device 100 isthinned. For example, the axial width of the hub 4 opposed to the coil12 may be 1 mm to 1.4 mm, and the axial width of the base member 3opposed to the coil 12 may be 0.6 mm to 0.9 mm. It is preferable to setboth the widths to these values in that the concern caused when thestiffness of the hub 4 is lowered is relieved. Alternatively, forexample, the axial width of the hub 4 opposed to the coil 12 may be 1.2mm, and the axial width of the base member 3 opposed to the coil 12 maybe 0.7 mm. It is advantageous to set both the widths to these values inthat the concern caused when the stiffness of the hub 4 is lowered isfurther relieved.

Next, in the disk drive device 200 according to the comparativetechnique shown in FIG. 4, a central portion of a clamper 70 is fixed toa central portion of a shaft 74 with a screw 72. For this reason, anaxial dimension of the central portion of the hub 56 is reduced by thedimensions of the clamper 70 and the screw 72. If the axial dimension ofthe central portion of the hub 56 is thinned, the resonance frequency ofthe disk drive device 200 may be lowered, the disk drive device 200 mayresonate with variation in drive torque and large oscillation may occur.

Referring back to FIGS. 2 and 3, to address this concern according tothe disk drive device 100 of this embodiment, the clamper 29 is arrangedon an upper surface of the lowered portion 4J of the hub 4. Acylindrical portion connecting the central portion 4I and the loweredportion 4J with each other is fitted to the central hole of the clamper29. The clamper locking portion that locks the clamper 29 is formed onthe upper surface of the lowered portion 4J. More specifically, theplurality of screw holes 4K are formed in the upper surface of thelowered portion 4J in its circumferential direction at equal intervals.These screw holes 4K constitute the clamper locking portion. The clamper29 is locked to the hub 4 by engaging the screws 30 with the screw holes4K. As a result, it is possible to relieve the concern caused When theaxial dimension of the central portion 4I of the hub 4 is reduced. It ispreferable to lock the clamper 29 to the huh 4 by engaging the screws 30with the screw holes 4K in that the shaft 16 can be formed to be longand it is possible to prevent the stiffness of the bearing from beingdeteriorated.

The screw hole 4K formed in the hub 4 has a concern that an axialdimension of its threaded portion cannot sufficiently be secured. Toaddress this concern, the screw hole 4K is formed to penetrate the hub4. In addition, a cover member 31 is provided on a portion of a surfaceof the hub opposed to the coil 12 where the screw hole 4K is formed. Asa result, it is possible to relieve the concern that the axial dimensionof the threaded portion of the screw hole 4K cannot sufficiently besecured. Various kinds of materials can be used for the cover member 31.A PET film may be pasted on the surface of the hub 4 opposed to the coil12 by a double-stick tape. This process is preferable in terms of easywork and in that it is possible to insulate between the hub 4 and thecoil 12.

Next, according to the disk drive device 200 of the comparativetechnique shown in FIG. 4, a cylindrical portion 76 and a bottom portion78 are independent members, and they are adhered and fixed to eachother. However, if the disk drive device 200 is thinned, the adheredportions of the cylindrical portion 76 and the bottom portion 78 arealso thinned. If the adhered portions are thinned, a bonding strengthbetween the cylindrical portion 76 and the bottom portion 78 isdeteriorated and there is a possibility that the adhered portions aredisconnected from each other by impact.

Referring back to FIG. 2, to address this concern according to the diskdrive device 100 of the embodiment, the housing 13 has a bottomed cupshape in which a cylindrical portion and a bottom portion are formedintegrally with each other. As a result, it is possible to relieve theconcern that the adhered portions of the cylindrical portion and thebottom portion of the housing 13 are disconnected from each other whenthe disk drive device 100 is thinned.

Next, in the disk drive device 200 of the comparative technique shown inFIG. 4, an annular member 80 is fixed to an inner periphery of theannular projection of the hub 56 by adhesion. The doughnut-shapedannular member 80 has an axial dimension of 1.2 mm or more to secure abonding strength with respect to the hub 56. If the disk drive device200 becomes thinner, the axial dimension of the cylindrical portion ofthe hub 56 also becomes thinner by a dimension of the annular member 80.If the axial dimension of the central portion of the hub 56 becomesthinner, a resonance frequency of the disk drive device 200 is lowered,and thus, the disk drive device 200 may resonate with variation in drivetorque and large oscillation may occur.

Referring back to FIG. 2, to address this concern, the bearing unit 5 ofthis embodiment includes the overhanging member 19 and the suspendingportion 20 that integrally rotates with the hub 4. The overhangingmember 19 is non-rotatably arranged at a position opposed to thesuspending portion 20 along the axial direction. The suspending portion20 cooperates with the overhanging member 19 to limit movement of thehub 4 in its axial direction. Widths of the overhanging member 19 andthe suspending portion 20 in the axial direction may be 0.6 mm or less.That is, a thickness of a disk portion 20A of the suspending portion 20may be 0.6 mm or less. As a result, even when the disk drive device 100is thinned, the axial dimension of the central portion 4I of the hub 4can be secured. It is preferable that the thickness of the disk portion20A of the suspending portion 20 be 0.4 mm or less in that the axialdimension, of the central portion 4I of the hub 4 can further bethickened.

According to the disk drive device 200 shown in FIG. 4, if the axialdimension of the annular member 80 is, reduced, a bonding strengthbetween the annular member 80 and the hub 56 is deteriorated. Therefore,there is a concern that these members are disconnected from each otherby impact. To address this concern, as illustrated in FIG. 2, thesuspending portion 20 of the disk drive device 100 is formed byintegrally forming the disk portion 20A opposed to the overhangingmember 19 in the axial direction and a cylindrical portion 20B connectedto an outer edge of the disk portion 20A. According to thisconfiguration, it is possible to sufficiently secure the axial dimensionof the cylindrical portion 20B that is bonded to the annular projection4E of the hub 4. As a result, it is possible to relieve the concern thatthe suspending portion 20 and the hub 4 are disconnected from eachother. For example, if the axial dimension of the cylindrical portion203 is set to 2.0 mm or more, the bonding strength between thesuspending portion 20 and the hub 4 can sufficiently be secured. If theaxial dimension of the disk portion 20A is set to 0.4 mm or less, theaxial dimension of the central portion 4I (see FIG. 3) of the hub 4 canbe increased.

There is a concern that much labor is required for machining thesuspending portion 20. To address this concern, in the disk drive device100, the suspending portion 20 may be formed by pressing a metalmaterial. As a result, it is possible to relieve the concern that muchlabor is required for machining the suspending portion 20.

A thrust dynamic pressure groove 23 may be formed in at least any ofsurfaces of the disk portion 20A of the suspending portion 20.Specifically, the thrust dynamic pressure groove 23 is formed in atleast one of a surface of the disk portion 20A opposed to the open endsurface of the housing 13 and a surface of the disk portion 20A opposedto the overhanging member 19. As a result, it becomes easy to machinethe thrust dynamic pressure groove 23.

Next, if the disk drive device 100, is thinned, this means that thestator core 11 is also thinned if the stator core 11 is thinned, thereis a possibility that the stator core 11 is mounted in an inclined statewhen the annular portion is fitted into the base member 3. To addressthis concern, in the disk drive device 100, a stator core support member32 is arranged between the base member 3 and the salient poles of thestator core 11 as illustrated in FIG. 2. The stator core support member32 annularly projects from the base member 3 toward a salient pole ofthe stator core 11 where the coil 12 is not provided. As a result, aninner periphery and an outer periphery of the stator core 11 aresupported by the base member 3. Therefore, by thinning the disk drivedevice 100, it is possible to relieve the concern that the stator core11 is inclined.

The stator core support member 32 is formed integrally with the basemember 3. This is preferable in that labor for assembling is notrequired. The stator core support member 32 may be arranged as a memberindependent from the base member 3. This is preferable because thestator core support member 32 can be made of various kinds of materialssuch as metal and plastic materials.

A portion of the hub 4 that covers an outer periphery of the magnet 21serves as a so-called back yoke. If the back yoke becomes thinner,magnetic reluctance is increased. If the magnetic reluctance isincreased, a magnetic flux generated by the magnet 21 is reduced. If themagnetic flux is reduced, torque is reduced, and there is a concern thata failure such as instability of rotation of the recording disk 1 iscaused. To address this concern, the hub 4 of the disk drive device 100includes the annular extending portion 40 extending outward. A diameterof an outer peripheral end of the annular extending portion 40 is largerthan that of the inner cylindrical portion 4D of the hub 4 by 4 mm ormore. As a result, since a sufficient thickness of the back yoke can besecured, it is possible to relieve concern caused by reduction intorque.

If a strong magnetic material is used to enhance a torque, a magneticflux in the back yoke may be saturated and a leakage flux may beincreased. If the leakage flux is increased, a noise signal is generatedin a magnetic head that reads data. If this noise signal is great, thereis a possibility that a failure occurs in a normal read operation and anormal write operation of magnetic data. To address this concernaccording to the disk drive device 100, saturation magnetic flux densityof the annular extending portion 40 that serves as the back yoke is setto 1 T (tesla) or more. According to this configuration, it is possibleto secure sufficient saturation magnetic flux density of the back yoke.Thus, it is possible to relieve the concern that the leakage flux isincreased. If the saturation magnetic flux density of the hub 4 is setto 1.2 T or more, a stronger magnetic material can be used.

It is also required to further enhance a torque and stabilize rotation.To meet this requirement according to the disk drive device 100, a gapbetween the magnet 21 and the tips of the salient poles of the statorcore 11 is set to 0.4 mm or less. As a result, since an air gap of themagnetic circuit becomes small, an amount of the magnetic flux of themagnet 21 is increased and a torque is thus enhanced. To secure aneffect of enhancement of the torque, it is preferable that the gapbetween the salient poles and the magnet 21 is 0.4 mm or less. To avoidcontact between the salient poles and the magnet 21, it is preferablethat the gap between the salient poles and the magnet 21 be 0.2 mm ormore.

The maximum energy product of the magnet 21 of the embodiment may be 10MGOe (megagauss oersted) or more. As a result, the amount of themagnetic flux of the magnet 21 is increased, and the torque is thusenhanced. The maximum energy product of the magnet 21 is preferably 10MGOe or more to secure the effect of enhancement of the torque. Tofacilitate magnetization, the maximum energy product of the magnet 21 ispreferably 16 MGOe or less. If a magnet 21 having such an maximum energyproduct and a back yoke having saturation magnetic flux density of 1 Tor more are combined, it is possible to suppress a leakage flux from theback yoke even if the disk drive device 100 is thinned.

As described above, it is required to further reduce, in thickness andweight, the disk drive device provided in a portable device. To meet therequirement according to the disk drive device 100 of the embodiment, ifan inner diameter of the recording disk 1 is set to 20 mm, a thicknessof the disk drive device 100 in the axial direction can be set to 7 mm,which is less than 7.5 mm. As a result, it is possible to reduce theportable device in thickness and weight. It is also possible tocontribute to saving resources.

As described above, the disk drive device 100 of the embodiment isfurther thinned so that it can suitably be used for a portable device,and can stably rotate the recording disk 1.

The disk drive device 100 can also be described as including the chassis10 having the base member 3 and the peripheral annular wall portion 15,the hub 4 on which the doughnut-shaped recording disk 1 is placed, thebearing unit 5 that is arranged on the base member 3 and rotatablysupports the hub 4, the spindle drive unit 6 that rotationally drivesthe hub 4, the head drive unit 17, the top cover 2 and the screw 9.Alternatively, the disk drive device 100 can also be described asincluding the stator 7 having a stationary member that does not rotateand the rotor 8 having a rotatable member, in which the stator 7 and therotor 8 include the bearing unit 5 that relatively rotatably supportsthe hub 4 and the spindle drive unit 6 that rotationally drive the hub4. The clamper 29 can be described as having the central hole fittedover the annular step between the central portion 4I and the loweredportion 4J. The annular outer cylindrical portion 4B can be described asbeing formed as a stepped portion which is recessed from the outerperipheral end of the lowered portion 4J. The back surface 30 of thebase member 3 can be described as being an upper surface on which thebearing unit 5 is arranged.

The invention is not limited to the above embodiment, and variousmodifications may be made thereto including design modifications basedon knowledge of a person skilled in the art. Configurations shown in thedrawings are explanatory only, and modifications can be made thereto aslong as similar functions can be achieved, and similar effects can beobtained therefrom.

While the invention has been illustrated and described in detail, theforegoing description is in all aspects illustrative and notrestrictive. It is therefore understood that numerous modifications andvariations can be devised without departing from the spirit and scope ofthe invention.

1. A disk drive device comprising; a base member; a hub on which arecording disk is to be placed; a bearing unit arranged on the basemember for rotatably supporting the hub; and a spindle drive unit forrotationally driving the hub, wherein the spindle drive unit includes: astator core having salient poles; a coil wound around each of thesalient poles; and a magnet having a plurality of magnetic polesarranged in a circumferential direction so as to be opposed to thesalient poles, the hub includes an outer cylindrical portion formed of amagnetic material and adapted to be engaged with an inner periphery ofthe recording disk, and an inner cylindrical portion fixing an outerperiphery of the magnet, the number of magnetic poles is an even numberin a range of 10 to 16, and the number of salient poles is a multiple of3 in a range of 12 to
 24. 2. The disk drive device according to claim 1,wherein the number of magnetic poles is 10 and the number of salientpoles is
 15. 3. The disk drive device according to claim 1, wherein thenumber of magnetic poles is 12 and the number of salient poles is
 18. 4.The disk drive device according to claim 1, wherein the number ofmagnetic poles is 14 and the number of salient poles is
 21. 5. The diskdrive device according to claim 1, wherein the number of magnetic polesis 16 and the number of salient poles is
 24. 6. The disk drive deviceaccording to claim 1, wherein the number of magnetic poles is 16 and thenumber of salient poles is
 12. 7. The disk drive device according toclaim 1, wherein a diameter of the inner cylindrical portion is largerthan that of the outer cylindrical, portion.
 8. The disk drive deviceaccording to claim 1, wherein a diameter of the outer cylindricalportion is 20 mm, an axial dimension between a surface of the coilopposed to the hub and a surface of the coil opposed to the base memberis 3 mm or less.
 9. The disk drive device according to claim 1, wherein,a surface of the coil opposed to the hub and a surface of the coilopposed to the base member are smoothened.
 10. The disk drive deviceaccording to claim 1, wherein a surface of the hub opposed to the coilis insulated.
 11. The disk drive device according to claim 1, wherein asurface of the base member opposed to the coil is insulated.
 12. Thedisk drive device according to claim 1, wherein an axial dimension of aportion of the hub opposed to the coil is larger than that of a portionof the base member opposed to the coil.
 13. The disk drive deviceaccording to claim 1, wherein the huh includes a lowered portion in asurface thereof on a side where the recording disk is placed, and aclamper locking portion is formed in the lowered portion for locking aclamper adapted to fix the recording disk to the hub.
 14. The disk drivedevice according to claim 13, wherein the clamper locking portion isprovided at two to five locations at equal intervals in itscircumferential direction avoiding the bearing unit in its radialdirection.
 15. The disk drive device according to claim 13, wherein theclamper locking portion is formed as a hole penetrating in its axialdirection, and a cover member is provided on a surface of the hubopposed to the coil where the clamper locking portion is formed.
 16. Thedisk drive device according to claim 1, wherein a gap between thesalient poles and the magnet is 0.4 mm or less.
 17. The disk drivedevice according to claim 1, wherein a diameter of a circumcircle of thesalient poles is larger than a diameter of the outer cylindricalportion.
 18. The disk drive device according to claim 1, wherein adiameter of the outer cylindrical portion is 20 mm, and an axialdimension from an end of the hub opposite from an end of the hub opposedto the base to an end of the base opposite from an end of the baseopposed to the hub is 6 mm or less.
 19. The disk drive device accordingto claim 1, wherein an inner diameter of the recording disk is 20 mm,and a thickness of the disk drive device is 7.5 mm or less.
 20. A methodfor producing the disk drive device according to claim 1, comprising:pasting a film on a surface of the hub opposed to the coil by anadhering member.